Internal electric field modulation by copper vacancy concentration of cuprous sulfide nanosheets for enhanced selective CO_(2) photoreduction

Although the internal electric field(IEF)of photocatalysts is acknowledged as a potent driving force for photocharge separation,modulating the IEF intensity to achieve enhanced photocatalytic performances remains a challenge.Herein,cuprous sulfide nanosheets with different Cu vacancy concentration were employed to study IEF modulation and corresponding direct charge transfer.Among the samples,Cu_(1.8)S nanosheets possessed intensified IEF intensity compared with those of Cu_(2)S and Cu_(1.95)S nanosheets,suggesting that an enhanced IEF intensity could be achieved by introducing more Cu vacancies.This intensified IEF of Cu_(1.8)S nanosheets induced numerous photogenerated electrons to migrate to its surface,and the dissociative electrons were then captured by Cu vacancies,resulting in efficient charge separation spatially.In addition,the Cu vacancies on Cu_(1.8)S nanosheets accumulated electrons as active sites to lower the energy barrier of rate-determining step of CO_(2)photoreduction,leading to the selective conversion of CO_(2)to CO.Herein,the manipulation of IEF intensity through Cu vacancy concentration regulation of cuprous sulfide photocatalysts for efficient charge separation has been discussed,providing a scientific strategy to rationally improve photocata lytic performances for solar energy conversion.

Enhancing an internal electric field by a solid solution strategy for steering bulk-charge flow and boosting photocatalytic activity of Bi_(24)O_(31)Cl_(x)Br_(10-x)

Constructing bismuth oxyhalide solid solutions with a single homogeneous phase have intrigued the research community;however,a deeper understanding of the intrinsic origin for improved bulk-charge separation is still unclear.Herein,a series of Bi_(24)O_(31)Cl_(x)Br_(10-x) solid solutions with the same structural characteristics were synthesized by crystal structure regulation.Combining density functional theory calculation,Kelvin probe force microscopy,and zeta potential testing results,an enhanced internal electric field(IEF)intensity between[Bi_(24)O_(31)]and[X]layers was achieved by changing halogen types and ratios.This greatly facilitated bulk-charge separation and transfer efficiency,which is significant for the degradation of phenolic organic pollutants.Owing to the enhanced IEF intensity,the charge carrier density of Bi_(24)O_(31)Cl_(4)Br_(6) was 33.1 and 4.7 times stronger than that of Bi_(24)O_(31)Cl_(10) and Bi_(24)O_(31)Br_(10),respectively.Therefore,Bi24O31Cl4Br6 had an optimal photoactivity for the degradation of bisphenol A,which was 6.21 and 2.71 times higher than those of Bi_(24)O_(31)Cl_(10) and Bi_(24)O_(31)Br_(10),respectively.Thus,this study revealed the intrinsic mechanism of the solid solution strategy for photocatalytic performance enhancement with respect to an IEF.

SPONTANEOUS POLARIZATION AND THE DISTRIBUTION OF INTERNAL STRESS AND ELECTRIC FIELDS AROUND A TRIPLE POINT

In this article, distributions of internal stress and internal electric fields around a triple point of ferroelectric polycrystals generated by the spontaneous deformation and spontaneous polarization were investigated. It was found that when all three grains consist of a single domain, the internal stresses and the internal electric fields do not vanish. Though it may be determined according to the principle of energy, the spontaneous configuration will not be unique without involving other conditions due to the symmetry of the crystal structure.

Superposition of dual electric fields in covalent organic frameworks for efficient photocatalytic hydrogen evolution

Covalent organic frameworks(COFs)are promising materials for converting solar energy into green hydrogen.However,limited charge separation and transport in COFs impede their application in the photocatalytic hydrogen evolution reaction(HER).In this study,the intrinsically tunable internal bond electric field(IBEF)at the imine bonds of COFs was manipulated to cooperate with the internal molecular electric field(IMEF)induced by the donor-acceptor(D-A)structure for an efficient HER.The aligned orientation of IBEF and IMEF resulted in a remarkable H_(2) evolution rate of 57.3 mmol·g^(-1)·h^(-1)on TNCA,which was approximately 520 times higher than that of TCNA(0.11 mmol·g^(-1)·h^(-1))with the opposing electric field orientation.The superposition of the dual electric fields enables the IBEF to function as an accelerating field for electron transfer,kinetically facilitat-ing the migration of photogenerated electrons from D to A.Furthermore,theoretical calculations indicate that the inhomogeneous charge distribution at the C and N atoms in TNCA not only pro-vides a strong driving force for carrier transfer but also effectively hinders the return of free elec-trons to the valence band,improving the utilization of photoelectrons.This strategy of fabricating dual electric fields in COFs offers a novel approach to designing photocatalysts for clean energy synthesis.

Revisiting N,S co-doped carbon materials with boosted electrochemical performance in sodium-ion capacitors:The manipulation of internal electric field

Heteroatom doping has emerged as a prevailing strategy to enhance the storage of sodium ions in carbon materials.However,the underlying mechanism governing the performance enhancement remains undisclosed.Herein,we fabricated N/S co-doped carbon beaded fibers(S-N-CBFs),which exhibited glorious rate performance and durableness in Na+storage,showcasing no obvious capacity decay even after 3500 cycles.Furthermore,when used as anodes in sodium-ion capacitors,the S-N-CBFs delivered exceptional results,boasting a high energy density of 225 Wh·kg^(-1),superior power output of 22500 W·kg^(-1),and outstanding cycling stability with a capacity attenuation of merely 0.014%per cycle after 4000 cycles at 2 A·g^(-1).Mechanistic investigations revealed that the incorporation of both pyridinic N and pyrrolic N into the carbon matrix of S-N-CBFs induced internal electric fields(IEFs),with the former IEF being stronger than the latter,in conjunction with the doped S atom.Density functional theory calculations further unveiled that the intensity of the IEF directly influenced the adsorption of Na+,thereby resulting in the exceptional performances of S-N-CBFs as sodium-ion storage materials.This work uncovers the pivotal role of IEF in regulating the electronic structure of carbon materials and enhancing their Na^(+)storage capabilities,providing valuable insights for the development of more advanced electrode materials.

Improvement of the Subcooling Problem of Sodium Acetate Trihydrate by a Combination of Stirring or Internal Electric Field and Nucleating Agent

Energy storage devices are the hub of a multi-energy complementary distributed energy system.Hydrated salts are the most suitable phase change material for energy storage devices,but subcooling is the main obstacle to their application.Nucleation requires a driving force so the use of nucleating agents alone does not reduce subcooling to a very low level.To address this issue,this paper first screened nucleating agents and then further reduced the subcooling of sodium acetate trihydrate in conjunction with stirring or direct current.The effects of rotor mass,rotational speed,direct current voltage,and electrode material on nucleation were analyzed.Finally,the stability of the composite phase change material in the presence of simultaneous stirring and energization was analyzed.The results showed that the addition of 1.5%in weight of disodium hydrogen phosphate dodecahydrate to sodium acetate trihydrate can reduce the subcooling to about 2.3℃.Continued addition of stirring or electricity can reduce the subcooling of sodium acetate trihydrate to within 0.5℃ or even eliminate it.The higher the momentum of the stirring,the better the improvement in subcooling,phase separation,and thermal conductivity.The higher the direct current voltage,the better the nucleation effect,but the electrode life will be lower.The silver electrode has the best nucleation effect.No new material was produced in the solution after 100 cycles in the presence of both stirring and direct current.The melting point of the phase change material was increased by 0.2℃ and the latent heat value decreased by 1.8%,still with good stability.The trace of deionized water should be added to the phase change material in subsequent studies to compensate for the consumption ofwaterby theanodicelution.

The first-principles study of ferroelectric behaviours of PbTiO3/SrTiO3 and BaTiOn/SrTiO3 superlattices

We have performed the first-principles calculation to investigate the origins of ferroelectricities and different po- larization behaviours of superlattices BaTiO3/SrTiO3 and PbTiO3/SrTiO3. The density of state （DOS） and electronic charge profiles show that there are strong hybridizations between atoms Ti and O and between atoms Pb and O which play very important roles in producing the ferroelectricities of superlattices BaTiO3/SrTiO3 and PbTiO3/SrTiO3. Ow- ing to the decline of internal electric field in SrTiO3 （ST） layer, the tetragonality and polarizations of superlattices decrease with increasing the fraction of SrTiO3 in the superlattices. We find that the polarization of PbTiO3/SrTiO3 is largerthan that of BaTiO3/SrTiO3 at the same ratio of components, because the polarization mismatch between PbTiO3 and SrTiO3 is larger than that between BaTiO3 and SrTiO3. The polarization and tetragonality are en- hanced with respect to those of bulk tetragonal BaTiO3 in the superlattices BaTiO3/SrTiO3, while the polarization and tetragonality are reduced with respect to those of bulk tetragonal PbTiO3 in superlattices PbTiO3/SrTiO3.

Rationally construction of atomic-precise interfacial charge transfer channel and strong build-in electric field in nanocluster-based Zscheme heterojunctions with enhanced photocatalytic hydrogen production

The lack of effective charge transfer driving force and channel limits the electron directional migration in nanoclusters(NC)-based heterostructures,resulting in poor photocatalytic performance.Herein,a Z-scheme NC-based heterojunction(Pt1Ag28-BTT/CoP,BTT=1,3,5-benzenetrithiol)with strong internal electric field is constructed via interfacial Co-S bond,which exhibits an absolutely superiority in photocatalytic performance with 24.89 mmol·h^(−1)·g−1 H_(2)production rate,25.77%apparent quantum yield at 420 nm,and~100%activity retention in stability,compared with Pt1Ag28-BDT/CoP(BDT=1,3-benzenedithiol),Ag29-BDT/CoP,and CoP.The enhanced catalytic performance is contributed by the dual modulation strategy of inner core and outer shell of NC,wherein,the center Pt single atom doping regulates the band structure of NC to match well with CoP,builds internal electric field,and then drives photogenerated electrons steering;the accurate surface S modification promotes the formation of Co-S atomic-precise interface channel for further high-efficient Z-scheme charge directional migration.This work opens a new avenue for designing NC-based heterojunction with matchable band structure and valid interfacial charge transfer.

Synergy of phosphorus vacancies and build-in electric field into NiCo/NiCoP Mott-Schottky integrated electrode for enhanced water splitting performance

Vacancy engineering and Mott-Schottky heterostructure can accelerate charge transfer,regulate adsorption energy of reaction intermediates,and provide additional active sites,which are regarded as valid means for improving catalytic activity.However,the underlying mechanism of synergistic regulation of interfacial charge transfer and optimization of electrocatalytic activity by combining vacancy and Mott-Schottky junction remains unclear.Herein,the growth of a bifunctional NiCo/NiCoP Mott-Schottky electrode with abundant phosphorus vacancies on foam nickel(NF)has been synthesized through continuous phosphating and reduction processes.The obtained NiCo/NiCoP heterojunctions show remarkable OER and HER activities,and the overpotentials for OER and HER are as low as 117 and 60 mV at 10 mA/cm^(2) in 1 mol/L KOH,respectively.Moreover,as both the cathode and anode of overall water splitting,the voltage of the bifunctional NiCo/NiCoP electrocatalyst is 1.44 V at 10 mA/cm^(2),which are far exceeding the benchmark commercial electrodes.DFT theoretical calculation results confirm that the phosphorus vacancies and build-in electric field can effectively accelerate ion and electron transfer between NiCo alloy and NiCoP semiconductor,tailor the electronic structure of the metal centers and lower the Gibbs free energy of the intermediates.Furthermore,the unique self-supported integrated structure is beneficial to facilitate the exposure of the active site,avoid catalyst shedding,thus improving the activity and structural stability of NiCo/NiCoP.This study provides an avenue for the controllable synthesis and performance optimization of Mott-Schottky electrocatalysts.

Superstable potassium metal batteries with a controllable internal electric field

Stable potassium metal batteries(PMBs)are promising candidates for electrical energy storage due to their ability to reversibly store electrical energy at a low cost.However,dendritic growth and large volume changes hinder their practical application.Here,referring to the morphology and structure of a virus,a bionic virus-like-carbon microsphere(BVC)was designed as the anode host for a PMB.A BVC with a three-dimensional structure can not only control the electric field,which can suppress dendrite formation,but can also provide a larger space to accommodate the volume change during the cycle progress.The designed potassium(K)metal anode exhibits excellent cycle life and stability(during 1800 h of repeated plating/stripping of K at a current density of 0.1 mA cm−2,K-BVC can realize a very stable K metal anode with low voltage hysteresis).Stable cyclability and improved rate capability can be realized in a full cell using Prussian blue over 400 cycles.This research provides a new idea for the development of stable K metal anodes and may pave the way for the practical application of next-generation metal batteries.

Regulating crystallinity in linear conjugated polymer to boost the internal electric field for remarkable visible-light-driven disinfection

Conjugated linear polymers are promising metal-free photocatalysts for visible-light-driven photocatalytic water disinfection,but it was still bottlenecked by the insufficient photogenerated charge separation and transport(CST)process.Herein,we obtained the highly crystalline imine-linked conjugated linear poly-mer(ODA-BPAH)with a greatly enhanced CST process.The highly crystalline ODA-BPAH exhibited excel-lent broad-spectrum water disinfection efficiency up to 99.99999%in 1 h,which is among the reported highest of state-of-the-art photocatalysts.The crystallinity of ODA-BPAH was regulated by simply turn-ing the solvent and the experiment results revealed that the ODA-BPAH with high crystallinity exhibited higher internal electric field strength and photocatalytic performance than that with low crystallinity,which indicates that higher crystallinity in linear conjugated polymers contributes to superior CST ef-ficiency as well as the generation of reactive oxygen species.This work highlights the impact of poly-mer crystallinity on the internal electric field and proves that linear poly-imine could be a new type of promising metal-free photocatalyst for water treatment.

Strong interface interaction and internal electric field promote electron transfer of Bi_(2)O_(2)S/NiFe_(2)O_(4) heterojunction for photocatalytic antibiotic degradation

Heterojunction photocatalysts have shown considerable activities for organic pollutants degradation.However,the faint connection interface and inferior charge shift efficiency critically block the property of heterojunction photocatalysis.Herein,Bi_(2)O_(2)S/NiFe_(2)O_(4) nanosheets heterojunction with ultrastrong inter-face interaction and high internal electric field are designed by an in-situ growth method.Tentative and theoretical consequences prove that the interfacial interaction and internal electric field not only act as the electron flow bridge but also decrease the electrons shift energy obstacle,thus speeding up electrons transfer and achieving effective spatial electron-hole separation.Therefore,a large amount of·O_(2)^(-)and holes as active species were generated.Remarkably,Bi_(2)O_(2) S/NiFe_(2)O_(4) establishes a considerably boosted photocatalytic performance for tetracycline degradation(0.032 min^(-1)),which is about 14.2-fold and 7.8-fold of the pristine BOS and NFO,respectively.This work provides a promising motivation for modulating charge transfer by interface control and internal electric field to boost photocatalytic performance.

Donor‐acceptor carbon nitride with electron‐withdrawing chlorine group to promote exciton dissociation

Carbon nitride(C_(3)N_(4))is promising for photocatalytic hydrogen production,but photogenerated electrons and holes in C_(3)N_(4)usually tend to exist as excitons due to intrinsic Coulomb interactions making its photocatalytic activity unsatisfactory.Herein,a well‐designed intramolecular C_(3)N_(4)‐based donor‐acceptor(D‐A)photocatalytic system was constructed to promote exciton dissociation.Due to its good chemical compatibility with melamine and appropriate sublimation property,2‐amino‐4,6‐dichloropyrimidine unit was chosen as the monomer to react with melamine to construct intramolecular D‐A system(CNCl_(x)).The hydrogen evolution rate of CNCl_(0.15)is 15.3 times higher than that of bulk C_(3)N_(4)under visible light irradiation,with apparent quantum efficiency of 13.6%at 420 nm.The enhanced activity is attributed to introduced electron‐withdrawing−Cl group as terminal group in the resulted CNCl_(x) samples,which can build internal electric field to promote the exciton dissociation into free electron and hole.In addition,lower work function value of CNCl_(x) samples indicates that internal electric field can help free electrons and holes transfer to the surface of CNCl_(x) samples for photocatalytic reaction.

内电场增强管状Z型In_(2)O_(3)/In_(2)S_(3)异质结的可控合成及光催化性能

构建具有特殊形貌和增强内电场的异质结材料可以有效提高光催化剂的光生电子-空穴对的分离效率,从而提升光催化活性。采用两步溶剂热+热解可控合成了金属有机骨架(MOFs)衍生的Z型In_(2)O_(3)/In_(2)S_(3)异质结,利用表征分析、光催化降解实验对构建的异质结物相、形貌、光学特性和活性进行了系统研究。结果表明,管状形貌的In_(2)O_(3)/In_(2)S_(3)具有强的光吸收响应,在In_(2)O_(3)和In_(2)S_(3)界面处形成的强内电场抑制了光生电子-空穴对的复合。在可见光照射下,质量比1∶1的In_(2)O_(3)/In_(2)S_(3)表现出最优异的光催化活性,在60 min内对盐酸四环素(TCH)的降解率达到68.44%,反应动力学常数分别比In_(2)O_(3)和In_(2)S_(3)提高了29.8和3.2倍,经3次循环表现出良好的稳定性。电化学测试和自由基捕获试验表明,In_(2)O_(3)/In_(2)S_(3)异质结内电场强度相比In_(2)O_(3)和In_(2)S_(3)分别提高了3.89和2.42倍,超氧自由基(·O_(2)^(-))和空穴(h^(+))是光催化过程中主要活性物质。该研究为强内电场异质结的高效光催化剂可控合成提供了一种有效策略。

一种新型等离子体共振效应调控的Ag/Ag_(3)PO_(4)/C_(3)N_(5)S型异质结光催化材料高效降解左氧氟沙星抗生素

抗生素在自然水体中的含量不断升高,引发的水体污染对社会的可持续发展构成了巨大威胁。光催化技术是一种高效且环保的环境净化技术,在解决环境污染方面具有巨大的应用前景。C_(3)N_(5)是一种性能优越的非贵金属光催化剂。然而,该催化剂的应用面临着一些挑战,比如光反应动力学较慢和光生载流子快速复合的问题。近期的研究表明,构筑独特的S型异质结是获得优良光催化剂的一种有效策略。因此,通过一种简易的制备方法成功构筑了一种等离子体效应协同的Ag/Ag_(3)PO_(4)/C_(3)N_(5)S型异质结光催化材料。由于等离子体效应和S型异质结的协同作用,Ag/Ag_(3)PO_(4)/C_(3)N_(5)异质结展现出优异的吸收太阳光的能力、高效分离光生载流子的能力以及强大的光氧化还原能力,能够在太阳光的激发下有效产生大量的·OH和·O_(2)^(-)自由基。因此,Ag/Ag_(3)PO_(4)/C_(3)N_(5)表现出卓越的光催化性能,对左氧氟沙星(LEV)的降解速率常数高达0.0362min^(-1),比C_(3)N_(5)、Ag_(3)PO_(4)和Ag_(3)PO_(4)/C_(3)N_(5)分别提高了24.8、1.1和0.7倍。此外,Ag/Ag_(3)PO_(4)/C_(3)N_(5)异质结具有出色的抗外界环境干扰性和可重复使用性。该研究为C_(3)N_(5)基光催化剂材料在环境净化方面迈出了坚实的一步。

肿瘤治疗电场的双层金属丝网传感器电场测试方法研究

目的提出并验证了一种双层金属丝网传感器(MWMS)测量肿瘤治疗电场(TTFields)的新方法。方法通过COMSOL建立圆柱模型并进行仿真,验证了双层MWMS的有效性。明胶和NaCl按照一定比例配置来模拟头颅内部组织和用猪肌肉替代肿瘤组织,并设计单层MWMS测量系统验证单层MWMS测量效果。结果仿真结果表明,双层MWMS在测量精度上明显优于单层MWMS。实际测试结果表明,单层MWMS可以测出模拟头颅内部组织区域的电场强度和猪肌肉所在位置。结论双层MWMS为TTFields的电场测量提供了更加精确的工具。

通过晶面调控产生强内建电场以提高卟啉光催化剂的H_(2)O_(2)生成速率

过氧化氢(H_(2)O_(2))是一种重要的化工产品,广泛应用于污水处理、消毒杀菌和印染漂白等领域.在蒽醌法生产H_(2)O_(2)的过程中,易产生有毒气体并存在爆炸危险.因此,仅利用水、氧气和太阳光即可在合适的光催化剂上生成H_(2)O_(2)的光催化技术备受关注.本课题组报道了通过酸碱自组装法制备的四(4-羧基苯基)卟啉(SA-TCPP)光催化剂,用于生产H_(2)O_(2).该催化剂克服了大部分H_(2)O_(2)光催化剂存在的需要牺牲剂、活性低和光利用率不足等问题,但其性能仍受限于较高的复合率.晶面调控已被证实是改善许多无机催化剂电荷复合的有效策略,然而,对于有机光催化剂,关于暴露晶面与其活性关系的研究仍然较少.本文采用溶解-重结晶法在水和三种有机溶剂的混合物中成功合成了三种具有不同暴露晶面的卟啉光催化剂.即利用卟啉在有机溶剂和水中的溶解度差异,将卟啉先溶解在四氢呋喃(THF)、甲醇(MeOH)或乙二醇(EG)溶液中,随后在水溶液中重新结晶.X射线衍射、高分辨率透射电子显微镜及晶面模拟模型图的结果表明,三种催化剂具有相同的晶体结构,但分别暴露了(400)、(022)和(020)晶面.通过紫外分光光度计测量这些催化剂在氙灯(λ≥420 nm)照射下的光催化活性,结果表明,具有(400)暴露面的卟啉光催化剂的H_(2)O_(2)生产速率最高,可达29.33 mmol L h^(-1)g^(-1),分别是具有(022)暴露面和(020)暴露面的卟啉光催化剂的2.7倍和4.1倍,约是已报道的SA-TCPP光催化剂的1.3倍.通过紫外漫反射、莫特肖特基曲线分析以及LED灯照射下的光催化活性测试,排除了光吸收能力对这三种卟啉光催化剂活性的影响.开尔文探针力显微镜、光生电流密度谱图、晶面模拟模型图和密度泛函理论计算结果表明,活性的差异主要归因于(400)表面暴露的高羧基含量所引发的强内建电场,并且在该暴露面上的内建电场方向有利于空穴从吡咯氮向羧基碳的跃迁,因此阻碍了电荷的快速重组,促进了富有挑战性的水氧化过程,而(020)面由于暴露了最多的吡咯氮和最少的羧基碳,其产生的内建电场强度最弱,且内建电场方向阻碍了空穴向羧基碳的跃迁,因此H_(2)O_(2)生产速率最低.综上所述,本工作通过晶面调控产生强内建电场以加速空穴的迁移,降低了电子空穴复合速率,实现了高H_(2)O_(2)生产速率,为更高效的有机光催化剂的设计和开发提供了新思路.

光栅光谱仪前置和后置分光构型下光调制反射谱应用的不同特征

光调制反射光谱因其高灵敏的特性而广泛的用于研究半导体及其表面与界面特性。基于光栅光谱仪其测量光路根据分光顺序的不同可以分为前置分光构型(暗构型)与后置分光构型(亮构型)。本文以InP/In_(0.52)Ga_(0.48)As/InP异质结外延结构为例,阐述了两种光路构型的不同特点和适用条件。揭示前分光构型能很好地分离荧光谱线与调制谱线;后分光构型则有利于采用较强调制激光而有效提取荧光较弱的电子结构信息。后分光构型实验中还观察到,当使用低能量激光(1064 nm)只调制激发窄带隙的InGaAs层时,却观察到宽带隙InP的谱线形的反常现象。这起源于光生载流子的界面电场调制作用,表明界面激发的后分光构型可作为一种非接触“电调制”方法而方便地应用于宽带半导体的异质外延结构的研究。

用于高效制氢的双S型ZnS/ZnO/CdS异质结构光催化剂

这项工作展示了一种新型具有高效光催化活性的双S型ZnS/ZnO/CdS三元异质结光催化剂。具有最佳CdS含量的样品,ZnS/ZnO/CdS-14%(ZZC14%),显示最大H2析出速率为4.1 mmol·g^(-1)·h^(-1)。最大光催化性能分别比相应的ZnS/CdS和ZnO/ZnS高出约2倍和13倍。在420 nm下,获得了19.8%的量子效率。此外,连续6次测试后,催化剂的结构和产氢活性保持微小的变化,表明了光催化剂的稳定性。根据理论计算和实验结果,光催化活性的显著提高归因于快速的电子转移和分离,以及双S型之间相互作用的紧密接触。这项工作强调了一种创新的方法来构建双S型光催化系统,该分解水产氢系统具有光生电荷载流子的高分离和快速迁移能力。

内建电场与偶极场协同增强SnNb_(2)O_(6)/富氮C_(3)N_(5)S型异质结光催化性能

定向电荷转移是调控光生载流子分离动力学的一种极具吸引力的策略。本文通过在SnNb_(2)O_(6)纳米片上原位生长C_(3)N_(5)纳米棒,设计一种具有强内建电场(IEF)和偶极场(DF)的新型2D/1D SnNb_(2)O_(6)/富氮C_(3)N_(5)S型异质结。通过构筑S型异质结,在界面处产生IEF,促进电荷从SnNb_(2)O_(6)向C_(3)N_(5)的定向迁移。与此同时,C_(3)N_(5)中的DF提供一种驱动力,将光生电子定向转移至活性位点。通过IEF和DF的协同效应,SnNb_(2)O_(6)/C_(3)N_(5)异质结实现了快速的定向电子转移,从而显著提高了电荷分离效率。研究结果表明,SnNb_(2)O_(6)/C_(3)N_(5)异质结的最佳产氢速率高达1090.0μmol·g^(-1)·h^(-1)(反应过程中持续释放H2气泡),分别是SnNb_(2)O_(6)和C_(3)N_(5)的38.8和10.7倍。此外,SnNb_(2)O_(6)/C_(3)N_(5)异质结在去除罗丹明B、四环素和Cr(Ⅵ)方面也表现出优异的光催化性能。通过电子顺磁共振(EPR)、时间分辨光致发光光谱(TPRL)和密度泛函理论(DFT)计算,本文系统探讨了SnNb_(2)O_(6)/C_(3)N_(5)异质结的定向电荷转移机制。这项研究为开发高效异质结光催化剂提供了一种可行的方法。